Synthesis of Silicon Nanoparticles and Nanowires by a Nontransferred Arc Plasma System

Choi, Sooseok; Lee, Hyunjun; Park, Dong-Wha

doi:https://doi.org/10.1155/2016/5849041

Journal of Nanomaterials

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Abstract Introduction Experimental Results and Discussion Conclusion Acknowledgments References Copyright Related Articles

Research Article | Open Access

Volume 2016 | Article ID 5849041 | https://doi.org/10.1155/2016/5849041

Synthesis of Silicon Nanoparticles and Nanowires by a Nontransferred Arc Plasma System

Sooseok Choi,¹Hyunjun Lee,²and Dong-Wha Park²

Academic Editor: Xiaopeng Li

Received21 Jul 2016

Accepted06 Sept 2016

Published24 Oct 2016

Abstract

Silicon nanomaterials were synthesized from solid silicon powder in microsize using a nontransferred arc plasma system. Synthesized silicon nanomaterials were sphere or wire in morphology according to the input power of arc plasma, the flow rate of plasma forming gas, and the collecting position of product. The product was spherical nanoparticles at a high input power for complete evaporation, while it was nanowires at a relatively low input power. The mean diameter of synthesized silicon nanoparticles was increased from 20.52 nm to 40.01 nm by increasing the input power from 9 kW to 13 kW. On the other hand, the diameter of silicon nanowires was controllable by changing the flow rate of plasma forming gas. The mean diameter of silicon nanowires was increased from 16.69 nm to 23.03 nm by decreasing the plasma forming gas flow rate from 15 L/min to 12 L/min.

1. Introduction

The photovoltaic (PV) and microelectronic industries have maintained over 30% of annual growth rate [1]. This industrial growth brings about a rapid increase in the production of silicon wafers. Silicon kerf loss is generated during wafer production processes such as block cutting and wafer sawing [2]. The amount of kerf loss in wafer production processes increases with the growth of silicon industry, though the kerf loss is considered as industrial waste. In order to save cost and to reduce energy consumption, lots of processes for the purification and the recycling of silicon kerf loss have been studied. They include superconducting magnetic separation [3], fractional melting [4], directional solidification [5], plasma oxidation [6], and electromagnetic separation [7] to recover highly purified silicon from silicon kerf loss. In addition, many researches have been studied to reuse silicon kerf loss and purified silicon [8, 9].

Nanostructured silicon material has various advantages in an integrated circuit (IC) and microfabrication technology. Therefore, many researchers have synthesized silicon nanomaterial by well-known methods such as nonthermal plasma processing using silicon tetrachloride and silane precursors [10, 11], the decomposition of silane and organosilane in gas phase reactions [12, 13], and liquid phase method with silicides precursors [14]. However, the preparation of silicon nanomaterial from solid phase is limited. It is because the vaporization of solid phase silicon materials requires considerable energy density. Silicon has a high latent heat for vaporization and a low thermal conductivity compared with typical metal. Moreover, the thermal conductivity of solid state silicon decreases with increasing temperature [15]. As a result, there is a limitation to prepare silicon nanomaterial from the evaporation of silicon in solid state.

Thermal plasma processing has been used to prepare nanomaterials with various advantages [16–18]. The high enthalpy of thermal plasma improves reaction kinetics and chemical reactivity. Thermal plasma has the region containing balanced charges of electrons and heavy particles such as radicals, ions, and neutrals with high temperature in local thermodynamic equilibrium [19]. Such active species allow the vaporization of any kind of raw material easily. Moreover, the rapid quenching of thermal plasma leads to the production of nanoparticles.

The arc thermal plasma system was used for the preparation of silicon nanomaterials with high productivity at a low cost [20]. The aim of this study is to investigate the synthesis of silicon nanomaterials from the vaporization of microsized silicon raw material. The vaporization of silicon feedstock was controlled by changing the plasma input power and the flow rate of plasma forming gas. In the product, both of nanosized silicon particles and wires were found. The formation routes for nanoparticles or nanowires were suggested from experimental results.

2. Experimental

The experimental equipment consists of a direct current (DC) power supply, a powder feeder, a plasma torch, a reaction tube, and a reaction chamber. The reaction tube maintains high temperature atmosphere after the ejection of thermal plasma jet at the torch exit, and the reaction is completed at the reaction chamber. Figure 1 is a schematic diagram of the arc thermal plasma system for the synthesis of silicon nanomaterial. The input power provided by the DC power supply was controlled at 7, 9, 11, and 13 kW, respectively. The flow rate of plasma forming argon gas was changed from 12 L/min to 15 L/min to control the velocity of plasma jet. The feeding rate and the argon carrier gas flow rate for the feeding of raw silicon powder were fixed at 0.2 g/min and 5 L/min, respectively. In the whole experiment, the arc thermal plasma system was operated at atmospheric pressure. The operating condition is summarized at Table 1.

Silicon nanomaterial was synthesized in the nontransferred arc plasma system from commercial silicon powder (40 μm, Aldrich, USA). Figures 2 and 3 are the field emission scanning electron microscopy (FE-SEM) images and the X-ray diffractometer (XRD) pattern of the silicon raw material. Figure 2 shows that angular silicon powder has broad size distribution and irregular shapes. Figure 3 indicates that peaks positions of XRD patterns have 2 theta values of 28.45 cm⁻¹, 47.31 cm⁻¹, and 56.14 cm⁻¹ corresponding to the crystal planes of (111), (220), and (311), respectively.

The injected raw powder into thermal plasma was vaporized by high temperature of thermal plasma jet and generating silicon nuclei, followed by the production of nanomaterial with rapid quenching. Products were collected from the inner surface of the reaction tube and the chamber cover, respectively. The morphology of silicon nanomaterial was analyzed by field emission scanning electron microscopy (FE-SEM, S-4300, Hitachi, Japan), and the size of nanomaterial was measured by an image process software (Image-Pro Plus, Media Cybernetics, USA). In addition, the phase of the product was identified by X-ray diffractometry (XRD, DMAX 2500, Rigaku, Japan).

3. Results and Discussion

3.1. The Effect of the Sampling Position

Figure 4 shows SEM images of products sampled at the reaction tube with different magnifications in the condition of 13 kW for the input power and 15 L/min for the flow rate of plasma forming gas. The product is composed of two different sizes of spherical particles. Figure 4(a) shows microsized particles, while Figure 4(b) shows nanoparticles condensed on the surface of a microsized particle [21]. Figure 5 shows SEM images of products sampled at the chamber cover in the condition of 13 kW for the input power and 15 L/min for the flow rate of plasma forming gas. Figure 5(a) shows well dispersed small products in contrast to Figure 4(a). These images show that the quantity of microsized particles at the chamber cover is smaller than those at the reaction tube. It is because more raw materials were vaporized along with the plasma flame. Therefore, sufficiently long residence time is required to vaporize the silicon raw materials completely.

(a)

(b)

(a)

(b)

Figure 6 shows the XRD patterns of raw material and synthesized silicon nanomaterials in the condition of 13 kW for the input power and 15 L/min for the flow rate of plasma forming gas. Figure 6 indicates that there are differences between the intensities of the silicon raw material and the synthesized nanomaterials. The silicon nanomaterials collected at the reaction tube and the chamber cover have low crystallinity compared with the silicon raw material. It is because the crystallization of product occurred with the growth of nanoparticles after vaporization in thermal plasma flow. From the same position of characteristic peaks, however, the physical phase of the product is the same with the raw material.

Average grain sizes of the raw material and products are estimated by the Scherrer equation from the full width at half maximum of XRD patterns [21]

The grain size, , can be calculated by the Scherrer constant (), the wavelength of X-ray (), diffraction angle (), and the corrected full width at half maximum (). Table 2 indicates the average grain size of the silicon raw material and products collected at the reaction tube and the reaction chamber prepared in the condition of 13 kW for the input power and 15 L/min for the flow rate of plasma forming gas. Calculated results show that the grain size of product from the reaction tube is larger than that from the chamber cover, while the particle size is the opposite results as shown in Figures 4(b) and 5(b). It is explained by a high temperature atmosphere with a strong radiation from thermal plasma in the reaction tube. Therefore, the crystallization of the silicon nanoparticles takes place after the formation of nanoparticles as well as during particle growth in the reaction tube. On the other hand, fabricated silicon nanoparticles at the chamber cover are relatively far from the plasma radiation leading to relatively weak intensities of characteristic peaks in XRD pattern.

3.2. The Effect of the Input Power

Figure 7 is a low resolution SEM image of fabricated silicon nanomaterials sampled at the chamber cover in different input powers of 7, 9, and 11 kW at the fixed plasma forming gas flow of 15 L/min. Figure 7 shows that microsized silicon raw material was partially vaporized. These images also show that the morphology of products is similar to the raw material. In comparison to Figure 5(a), the input power of 13 kW is required for the complete evaporation of silicon raw material. Figure 8 is a high magnification SEM image at the same condition with Figure 7. Most of products is nanosized spherical particles, while some of them are nanowires. Figure 8(a) was synthesized in the condition of 7 kW for the input power and it shows spherical nanoparticles. Figures 8(b) and 8(c), however, show silicon nanomaterials with nanowires and nanoparticles. Hafiz et al. explained the synthesis mechanism of silicon nanowire which is produced in two-step processes using hypersonic plasma particle deposition with TiSi₂ catalyst [22], and Meshram et al. introduced the synthesis method of silicon nanowire using tin catalyst in a hot wire chemical vapor process [23]. On the other hand, metal catalyst was not used in the present work. Instead of the catalyst, the influences of the plasma flow on wire formation were hypothesized when the nontransferred arc thermal plasma system is employed to produce silicon nanomaterial. Silicon raw material is partially vaporized in the reaction tube due to a high velocity of plasma jet [24]. Therefore, surface evaporation takes place in the reaction tube, and viscid molten silicon is expected in core region. As a result, it is hypothesized that the viscid molten silicon droplets are stretched by the momentum transfer from the high velocity of thermal plasma jet forming the wire structure of silicon.

(a)

(b)

(c)

(a)

(b)

(c)

The wire structured silicon is frequently observed at the condition of 11 kW for the input power rather than at the condition of 9 kW. There are two reasons to support such result. The first one is the low viscosity of the molten silicon in the case of 11 kW in comparison with the case of 9 kW. The viscosity of the molten silicon material is decreased with increasing the silicon temperature [25]. The other is the high plasma velocity. The velocity of thermal plasma at the condition of 11 kW for the input power is faster than that at 9 kW [24]. The velocity of thermal plasma jet has influence on the acceleration and stretching of molten silicon particles. Therefore, it is supposed that the wire structure is formed effectively at 11 kW with the low viscosity of molten silicon and the high velocity of thermal plasma jet.

Figure 8(c) shows silicon nanoparticles as well as silicon nanowires. When the silicon raw materials passed the plasma jet in the high temperature region, the silicon nanoparticles were formed by the vaporization and condensation processes [21, 26–29]. On the other hand, some nanoparticles were formed after the formation of nanowires. A low thermal conductivity of silicon compared with typical metal hinders the internal heat transfer of silicon. The surface vaporization of silicon wire occurred by the energy stored in the molten wire. This silicon vapor prepared by the surface vaporization was nucleated, and then spherical nanoparticles were condensed. On the other hand, only spherical nanoparticles were observed in Figure 5(b) at the highest input power of 13 kW. In this case, enough energy was supplied for the complete evaporation of the raw materials within the residence time. This sufficient energy for full vaporization of the silicon materials was supplied by the high plasma gas temperature in the case of 13 kW for the input power [30].

Figure 9 shows the particle size distribution of nanoparticles collected at the chamber at three different input powers of 9, 11, and 13 kW. The particle size distribution is relatively narrow at the condition of 9 kW for the input power. On the other hand, the particle size distribution is broad at the condition of 13 kW. The size distribution of the nanoparticles increases by increasing the arc plasma input power. Table 3 is the particle mean size sampled at the chamber cover at different input powers of 9, 11, and 13 kW. The particle mean sizes were 20.52 nm, 35.61 nm, and 40.01 nm at 9 kW, 11 kW, and 13 kW for the input powers, respectively. The particle mean size increases depending on the amount of silicon vapor in the reactor. The quantity of silicon vapor is determined by the plasma input power at a fixed raw material feeding. More heat is transferred to feeding powder at the highest input power of 13 kW, and then the amount of the silicon vapor in the reactor is increased [31]. Such large amount of silicon vapor in a high input power leads to the supersaturation of the silicon at a high temperature. The nucleation of the silicon vapor is affected by supersaturation of silicon vapor at a high temperature, and nucleated silicon materials in a high power have a long residence time to condense into silicon nanoparticles. Such tendencies result in the broad particle size distribution and the large mean size of the silicon nanoparticles [29]. A small amount of silicon is vaporized at the surface of silicon materials at a low input power condition. Such silicon vapor produces silicon nanoparticles with a small mean diameter attached to the surface of partially evaporated microsized silicon materials.

(a)

(b)

(c)

3.3. The Effect of the Flow Rate of Plasma Forming Gas

Figure 10 is the SEM image of the synthesized silicon product collected at the chamber cover. Thermal plasma was operated at 11 kW for the input power and 12 L/min for the flow rate of plasma forming gas. In this condition, the flow rate of plasma forming argon gas was decreased compared with the operating condition for Figure 8(c). The velocity of plasma flame is decreased by decreasing the gas flow rate from 15 L/min to 12 L/min. The average diameter of silicon nanowire was 16.69 nm at the flow rate of 15 L/min. On the other hand, silicon nanowires produced at 12 L/min were 23.03 nm in average diameter. This result indicates that the formation of the nanowires is affected by the plasma velocity. The average diameter of the silicon nanowires was decreased with increasing the plasma velocity.

3.4. Synthesis Mechanism of Silicon Structure

Nanoparticles are produced through the homogeneous nucleation and heterogeneous condensation when the vaporization and condensation processes are considered. The first step of the process is the vaporization of the raw material by the high enthalpy of the arc thermal plasma. Feeding particles move along the plasma flow to the tail of the plasma jet. The temperature of the plasma flow is rapidly decreased transferring the energy to the raw material. The vapor is saturated by such quenching process. Therefore, the homogeneous nucleation and heterogeneous condensation are followed, and this series of process results in the production of nanoparticles [21, 26–29].

Silicon nanoparticles and nanowires were fabricated in this study. It is hypothesized that this phenomenon is caused by unique properties of silicon such as a high thermal conductivity compared to the metal materials, large latent heat, and a high vaporization point. In addition, the synthesis of the silicon nanomaterials is affected by the unique characteristics of the rapid quenching of arc thermal plasma. Figure 11 explains a synthesis mechanism of silicon nanomaterial by arc thermal plasma. Figure 11(a) shows the process that the silicon nanoparticles are synthesized when raw material is fully evaporated. Silicon vaporizes steadily due to a low thermal conductivity and a high vaporization enthalpy. The raw material can be fully evaporated with a sufficient heat transfer from thermal plasma. The supersaturated silicon vapor is prepared by the decrease of the silicon vapor temperature with the rapid quenching rate. This supersaturated silicon vapor is nucleated to produce stable phase. After the nucleation process, the growth is followed through the heterogeneous condensation. Therefore, silicon nanoparticles are fabricated by vaporization and condensation process.

Table 4 shows the thermal properties of copper, aluminum, silicon, and alumina. Copper and aluminum have favorable conditions to be vaporized, because the latent heat of metal is lower than that of silicon, and the thermal conductivity of metal is higher than that of silicon. The synthesis of nanomaterials has been studied by an enough enthalpy and a high temperature of thermal plasma for the complete evaporation. Alumina which is ceramic material has lower thermal conductivity than that of silicon and metals. The spheroidization of the ceramic material has been studied by the melting of ceramic material using a thermal plasma system [32, 33]. Silicon material has the thermal properties between metal material and ceramic material. Therefore, silicon is vaporized more slowly than metal and silicon is believed in both of liquid and gas states in thermal plasma region. Figure 11(b) shows the suggestion of silicon nanowire formation. Silicon raw materials received a certain amount of heat passing through thermal plasma jet in melting state. The viscosity of molten silicon which is partially vaporized is decreased with increasing its temperature by heat transfer from thermal plasma, and viscid molten silicon starts to be evaporated from surface. Such heated viscid silicon droplets get momentum by a rapid velocity of plasma gas flow and deform the shape of the viscid molten silicon to the wire structure. Therefore, silicon nanowires are produced when the molten silicon nanowires are cooled down by the rapid quenching of thermal plasma jet.

4. Conclusion

Silicon nanomaterial was synthesized by the nontransferred arc thermal plasma system. The solid silicon powder with 40 μm size was used as raw material. Nontransferred arc thermal plasma was required for the vaporization of the silicon material because silicon materials have a low thermal conductivity and high latent heat. Treated silicon nanomaterial products from the chamber cover were nanoparticles and nanowires. The formation mechanism of silicon nanomaterial suggested that the synthesis of the nanowire is affected by the viscosity and the flow rate of the plasma forming argon gas. Therefore, the diameter of the nanowires was increased from 16.69 nm to 23.03 nm with decreasing the flow rate of plasma forming gas. On the other hand, only silicon nanoparticle was found at 13 kW for input power and at 15 L/min for gas flow rate. It was hypothesized that the silicon nanowires are synthesized by the strain of molten silicon with a low thermal conductivity, and the series of the fabrication of the silicon nanowires is affected by the rapid velocity of the plasma forming gas, when the raw silicon materials were not sufficiently vaporized. Contrary to this, when the raw silicon materials were fully vaporized in the condition of 13 kW for the input power, only spherical silicon nanoparticles were fabricated from the silicon vapor by the vaporization-condensation process. Therefore, sufficient heat transfer from thermal plasma to silicon is required to synthesize silicon nanoparticles. Since the working gas influences heat transfer, researches about working gas species and gas injection method to control silicon nanosized products will be carried out as future work. In addition, effect of operating condition on properties of silicon nanomaterials will be studied for practical application of silicon nanomaterials from silicon kerf loss.

Competing Interests

The authors declare that they have no competing interests.

Acknowledgments

This work was supported by the Regional Innovation Center for Environmental Technology of Thermal Plasma (ETTP) at INHA University, Korea, designated by the Ministry of Trade, Industry and Energy (2016), and by the Basic Science Research Program through the National Research Foundation of Korea (NRF) funded by the Ministry of Education of the Republic of Korea (no. NRF-2010-0020077).

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Copyright © 2016 Sooseok Choi et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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